RU68069U1 - INTELLIGENT INTEGRATED SAFETY SYSTEM FOR GAS-TURBINE POWER INSTALLATION - Google Patents

Abstract

The utility model relates to security equipment and is intended to ensure the safety of a gas turbine power plant. The purpose of creating a utility model: improving security. The solution of these problems was achieved in an intelligent integrated security system for a gas turbine power plant, containing a container in which a gas turbine engine and a free turbine connected with a payload are installed, characterized in that at least one video camera is installed inside the container and connected via a video capture card to computer, access system sensors and fire system sensors connected through the controller to the computer. At least one video camera connected via a video capture card to a computer can be installed outside the container. A fire extinguishing system can be installed inside the container and externally, connected through a controller to a computer. Outside the container, light and sound detectors are installed, connected through a controller to a computer. 1 sec P.-ct. f-ly, 3 head, P.-ct., ill. - 2

Description

The utility model relates to the field of energy and can be used to generate electricity and heat (in the form of steam or hot water) as part of existing or newly constructed thermal power plants, and also as a locomotive drive (gas turbine).

The main field of application is stationary containerized and transported power plants based on a gas turbine engine with a free turbine.

A known gas turbine installation comprising a frame, a gas turbine engine with a power turbine, a turbine diffuser and payload units, as well as an air intake and exhaust device (Japanese Patent No. 08270458, F02C 7/04, 1996).

The installation has a low efficiency due to significant pressure losses and turbulence of the air flow in the inlet device, as well as an increased level of noise and losses in the suction and exhaust paths.

A gas turbine power unit is known, including a container, a gas turbine engine with a power turbine, a transmission, a turbine diffuser and a payload assembly, as well as an air intake and exhaust device (RF Patent No. 2193678, F02C 7/04, 04.12.2000).

The well-known power unit allows only certain types of gas turbine engines to be used, since power is taken from the engine in it from the compressor side, for example, a turboprop engine or a turbojet dual-circuit engine in which the first stage of the compressor is removed, and the released power is transferred to the payload drive. In addition, this power unit does not use all the possibilities for using the energy of burned fuel, and for dual-circuit engines, the service life is reduced due to the overhaul of previously used engine modules.

Use all types of gas turbine engines for the same purpose as the claimed technical solution allows gas turbine power unit according to the patent of the Russian Federation No. 2144645, F02C 7/25, 05/17/1996, prototype. A gas turbine power unit is the closest analogue to the claimed technical solution and contains a container with a gas turbine engine, a power turbine, a payload unit and a transmission connecting the latter with a power turbine, a turbine diffuser, as well as an air intake and exhaust device. However, in this power unit

also, all the possibilities for using the energy of fuel burned out in the engine are not used.

The solution of these problems was achieved in an intelligent integrated security system for a gas turbine power plant, containing a container in which a gas turbine engine and a free turbine connected with a payload are installed, characterized in that at least one video camera is installed inside the container and connected via a video capture card to computer, access system sensors and fire system sensors connected through the controller to the computer. At least one video camera connected via a video capture card to a computer can be installed outside the container. A fire extinguishing system can be installed inside the container and externally, connected through a controller to a computer. Outside the container, light and sound detectors are installed, connected through a controller to a computer.

The proposed technical solution has novelty and industrial applicability, as evidenced by patent research. To implement the utility model, it is sufficient to use well-known components and parts previously developed and implemented in the design of gas turbine engines and in mechanical engineering.

The essence of the utility model is illustrated in figure 1 ... 2, where:

- figure 1 shows the first diagram of the security system of the power plant of a gas turbine,

- figure 2 is a diagram of the cooling and fire fighting,

The proposed technical solution (Fig. 1) contains a gas turbine engine GTE 1 and a free turbine 2 installed at the exit of the gas turbine engine 1. The cavity at the outlet of the free turbine 2 is formed by the body of the free turbine 3. An exhaust device 4 is installed at the exit of the free turbine 2 .

The gas turbine engine 1 contains an input device 5, a compressor 6, a combustion chamber 7 having a fuel supply system 8 and a fuel pump 9. The turbine engine includes a turbine 10.

An electric generator 11 is connected to a free turbine 2.

The generator 11 is designed to generate electricity for peak power plants or to drive a gas turbine locomotive and through electrical connections 12 through a switch 13 is connected to drive electric motors 14, which, in turn, are connected to drive wheel pairs 15. With one of the rotors of the turbine engine 1, preferably with a rotor the third cascade of the gas turbine engine 1 through the shaft 16, the disengaged clutch 17 and the primary shaft of the auxiliary diesel 18 connected auxiliary diesel 19,

designed for maneuvering a gas turbine locomotive and for starting a gas turbine engine 1. An auxiliary diesel generator 23 is connected to the auxiliary diesel engine 17, specifically to its output shaft 20 through the coupling 21 and the shaft of the auxiliary electric generator 22, designed to maneuver the gas turbine locomotive and power auxiliary electricity consumers when the gas turbine power plant is not works.

Compressor 6 (FIG. 1) consists of a cascade of a low-pressure compressor 24, a cascade of a medium-pressure compressor 25, and a cascade of a high-pressure compressor 26. The turbine 10 consists of a high-pressure turbine 27, a medium-pressure turbine 28, and a low-pressure turbine 29. Free turbine 2 consists of an adjustable guide apparatus 30 with a control drive 31 and at least one impeller of a free turbine 32.

GTE 1 has an outer casing 33, the temperature of which can reach 100 ... 130 0C, which is unsafe during maintenance. In addition, on the surface of the outer casing 33, control and regulation units are located, access to which is absolutely undesirable. Also, when transporting the power plant from the manufacturer to the customer, these units can be damaged. To eliminate these shortcomings, the power plant is installed in the container 34. For servicing the units, closing hatches 35 are provided. The power plant in the container 34 is installed on the front legs 36 and the rear legs 37. The front legs 36 are fixed and the rear legs 37 are made with the possibility of horizontal movement for compensation of thermal expansion. The cooling system of the outer casing 33 of the turbine engine 1 is provided, combined with fire extinguishing systems. The internal cavity of the container “B” is connected to the atmosphere through the discharge pipe 38 or to the internal cavity “B” of the exhaust device 4. A temperature sensor 39 is installed on the discharge pipe 38 from the cooling system, which monitors the temperature of the air discharged from the cooling system and simultaneously acts as a control sensor fire occurrence.

In the control circuit of the power plant is provided, the control unit 40, at least one speed sensor 41, connected to it by electrical connections 12.

An original feature of the power plant is that it is equipped with a cooling system (GTE 1 and free turbine 2), combined with three fire extinguishing systems.

Figures 1 and 2 show a cooling system combined with fire extinguishing systems.

This system contains four systems:

- cooling air supply system - 42,

- engine fire extinguishing system - 43,

- container fire extinguishing system - 44,

- fire extinguishing system with water - 45.

The cooling air supply system 42, contains an annular air intake manifold 46 mounted on the casing 33 of the turbine engine 1, the cavity of which, through the holes “G”, communicates with the cavity behind the first stage of the first compressor stage. A sampling valve 47 having a valve actuator 48 is installed on it, an annular air supply manifold 49 is connected to the outlet of the sampling valve. An annular air supply 49 is installed in the cavity of the container “B”.

The fire extinguishing system of the engine 43 contains at the entrance to the turbine engine 1 an internal annular manifold 50 connected through a valve 51 to an inert gas cylinder 52. This system is designed to extinguish a fire within the gas turbine engine 1.

The fire extinguishing system of the container 44 includes an air supply manifold 49 connected through an valve 53 to an inert gas bottle 52 and is designed to extinguish a fire within the container 34.

The fire water extinguishing system 45 comprises a water tank 54, to the outlet of which a water pump 55, a valve 56, and one or more water spray manifolds 57 are connected (FIG. 2).

At least one video camera 58 and at least one thermal imager 59 are connected inside the container 34 and connected via a video capture card 60 to a computer 61 (system unit) to which a monitor 62 and a control device 63, such as a keyboard, are connected. By electrical communication 64, the computer 61 is connected to the control unit 40. At least one video camera 65 for external observation can be installed on the container 34 from the outside. At least one lighting device 66 may be installed inside the container 34. Access control sensors 67, fire sensors 68, light and / or sound annunciators 69 are connected to a computer 61 through a controller 70. The payload 11 is located in an additional container 70.

The security system of an energy gas turbine power plant operates as follows.

When starting the power plant, an electric signal is supplied from the control system 40 to the auxiliary diesel engine 19, which serves as a starter (Fig. 1) and to the fuel pump 9. The auxiliary diesel engine 19 spins the rotor of the high-pressure compressor stage and the low-pressure turbine 29. The power of the auxiliary diesel engine 19 is wasted to promote only one of the three rotors of the GTE 1, this facilitates and accelerates

launch. The rotors of medium and low pressure and the rotor of a free turbine 2 are untwisted.

When the start of the gas turbine engine GTE 1, its speed is reached by the workers, which is controlled by the speed sensor 41, the control unit 40 gives a signal to limit the fuel supply. Next, from the control unit 40, a signal is supplied to the valve actuator 48, which opens the air bleed valve 47. Air through the openings “E” enters the container “B” into the cavity. Temperature sensors 39 monitors the temperature of the air at the outlet of the cooling systems and regulates the radial clearances and transmits this data to the control unit 40. When the temperature of the outlet air exceeds, for example, more than 95 ° C, the control unit 40 sends a signal to the actuator 48 to open the selection valve air 47 (figure 2). At temperatures below 80 ° C, a signal is sent to cover the air bleed valve 47. This allows maintaining a minimum radial clearance between the rotor blades and the stators of compressors, turbines and a free turbine. As a result, the efficiency of the power plant will increase by 2 ... 4% compared with the best world models of products of similar purpose, and fuel consumption will decrease accordingly. In addition, the outer surface of the container will have a temperature of not more than 40 ° C, which will ensure the safety of maintenance.

The temperature of the walls of a gas turbine engine and a free turbine is controlled by a thermal imager 59, which transmits information about the temperature of the walls with an accuracy of 0.1 ° C to a computer 61 and then to a monitor 62 in the form of a multi-color image, on which, for example, red color indicates overheating. Video camera 58 allows you to visually monitor the state of the cavity "B", for example, the penetration of unauthorized persons into the container or blockage. The video camera 65 allows you to control the room (compartment) of the gas turbine locomotive in which the power plant is installed.

At the same time, a gas turbine locomotive (locomotive) has the ability to use the power of a gas turbine engine 1 in the range from 6 to 40 MW when driving, compared with the maximum power of locomotives used in the Russian Federation 1800 kW, which will reach a speed of 500 km / h or more.

When entering the container

The access control sensor 67 is activated and the signal is transmitted to a computer 61 and then to a light or sound detector 69.

In case of fire

The occurrence of a fire is monitored by a temperature sensor 39 and other fire detection sensors 68, which can be arbitrarily many and can be placed in a gas turbine engine 1, inside the container 34 and outside it.

First of all, turn off the fuel pump 9. Then, valves 51 and 53 are opened and inert gas is supplied into the gas turbine engine 1 and inside the container 34. If necessary, the water pump 55 is started and the valve 56 is opened to supply water to the outer surface of the container 34. This extinguishing method has a number advantages:

- The localization of the fire inside the gas turbine engine is fast and does not lead to the destruction of the material part, because when water gets on very hot parts, the gas turbine engine could lead to warpage and breakage.

- When the fire is localized inside the container 34 with inert gas, the cables of the gas turbine engine control systems 1 are not wetted and brought into an inoperative state.

In an emergency, using the control device 63 through the computer 61 and the control unit 40, the driver can command the emergency shutdown of the power plant or the inclusion of one of the fire extinguishing systems.

- The consumption of inert gas and water to extinguish is small, because in is spent purposefully in a certain amount.

- There is no harmful effect of the use of fire extinguishing means on staff and passengers.

Application of the utility model allowed:

1. Ensure the safety of the installation by reducing noise, insulation and installing a very effective multi-stage fire extinguishing system.

2. Prevent a terrorist act in transport.

3. Visually monitor the situation both inside the container and outside.

4. To control overheating of individual nodes.

5. Ensure fire safety of the facility.

6. Provide protection against unauthorized access to the facility.

7. Facilitate (accelerate) the launch of the power plant of a gas turbine transported power plant.

8. Improve the reliability of the power plant

9. Improve the efficiency of the installation.

10. Facilitate assembly through the modular design of the installation.

11. Create conditions for transportation.

12. Ensure maintainability of the installation.

Claims (4)

1. Intelligent integrated security system of a gas turbine power plant containing a container in which a gas turbine engine and a free turbine connected with a payload are installed, characterized in that at least one video camera is installed inside the container and connected via a video capture card to a computer, sensors access systems and fire system sensors connected through a controller to a computer. 2. The intelligent integrated security system of a gas turbine power plant according to claim 1, characterized in that at least one video camera is connected outside the container and connected via a video capture card to a computer. 3. The intelligent integrated security system of a gas turbine power plant according to claim 1 or 2, characterized in that a fire extinguishing system is installed inside the container and externally, connected through a controller to a computer. 4. The intelligent integrated security system of a gas turbine power plant according to claim 1 or 2, characterized in that light and sound detectors are installed outside the container and connected through a controller to a computer.